GRAVITINO DARK MATTER

GRAVITINO DARK MATTER Wilfried Buchmüller DESY, Hamburg LAUNCH09, Nov. 2009, MPK Heidelberg

Why Gravitino Dark Matter? Supergravity predicts the gravitino, analog of W and Z bosons in electroweak theory; may be LSP, natural DM candidate: m 3/2 < 1keV, hot DM, (Pagels, Primack 81) 1keV < m 3/2 < 15keV, warm DM, (Gorbunov, Khmelnitsky, Rubakov 08) 0keV < m 3/2 < MeV, cold DM, gauge mediation and thermal leptogenesis (Fuji, Ibe, Yanagida 03); recently proven to be correct by F-theory (Heckman, Tavanfar, Vafa 08) GeV < m 3/2 < 1TeV, cold DM, gaugino/gravity mediation and thermal leptogenesis (Bolz, WB, Plümacher 98) Baryogenesis, (gravitino) DM and primordial nucleosynthesis (BBN) strongly correlated in cosmological history. 1

Gravitino Problem Thermally produced gravitino number density grows with reheating temperature after inflation (Khlopov, Linde 83; Ellis, Kim, Nanopoulos 84;...), n 3/2 n γ α 3 M 2 p T R. For unstable gravitinos, nucleosynthesis implies stringent upper bound on reheating temperature T R (Kawasaki, Kohri, Moroi 05;...), T R < O(1) 5 GeV, hence standard msugra with neutralino LSP incompatible with baryogenesis via thermal leptogenesis where T R GeV!! Possible way out: Gravitino LSP, explains dark matter! 2

Gravitino Virtue Can one understand the amount of dark matter, Ω DM 0.23, with Ω DM = ρ DM /ρ c, if gravitinos are dominant component, i.e. Ω DM Ω 3/2? Production mechanisms: (i) WIMP decays, i.e., Super-WIMPs (Covi, Kim, Roszkowski 99; Feng, Rajaraman, Takayama 03), Ω 3/2 = m 3/2 m NLSP Ω NLSP, independent of initial temperature T R (!), but inconsistent with BBN constraints; (ii) Thermal production, from 2 2 QCD processes, Ω 3/2 h 2 0.5 ( TR GeV ) ( 0GeV m 3/2 )( ) m g (µ) 1TeV Ω DM h 2 for typical parameters of supergravity and leptogenesis!. 3

Leptogenesis, GDM and BBN (Bolz, WB, Plümacher 98) Left: Gravitino abundance as function of reheating temperature. Right: Upper bound on gluino mass, lower bound on higgsino NLSP; shaded area: BBN ok. Note: gaugino mass unification not possible. Improved BBN constraints τ NLSP...... Pospelov 06... review Steffen 08 4

Reheating: initial RH-neutrino dominance (...Asaka et al 99; Hahn-Woernle, Plümacher 08; Erbe 09) Reheating process from inflaton decay: φ N 1 N 1 (lh)(lh)...; combined system of Boltzmann eqs connects LG and gravitino production M 3 = 400 GeV 0.2 0.18 0.16 0.14 Dark Matter Region K= K=500 Ω G ~h 2 0.112 0.095 0.08 0.07 0.06 0.05 1 m G ~ [GeV] parameters: M 1 = 9 GeV T R, m g = 1 TeV; for K = (strong washout): m 3/2 6 GeV (cf. thermal LG: Ωh 2 1). 5

Decaying GDM (WB, Covi, Hamaguchi, Ibarra, Yanagida 07) BBN, leptogenesis and gravitino dark matter are all consistent in case of a small R-parity breaking, which leads to processes τ R τ ν µ,µ ν τ, τ L b c t,... and also ψ 3/2 γν. Small R-parity breaking can occur together with B-L breaking, λ h (e,d) Θ < 7, Θ v2 B L M P 2. The NLSP lifetime becomes sufficiently short (decay before BBN), cτ lep τ 30 cm ( ) ( ) 1 2 m τ λ 200GeV 7. BBN, thermal leptogenesis and gravitino dark matter are consistent for 14 < λ, λ < 7 (B, L washout) and m 3/2 > 5 GeV. 6

At LHC one should see characteristic signal with strongly ionising macroscopic charged tracks, followed by a muon track or a jet and missing energy, corresponding to τ µν τ or τ τν µ. The gravitino decay ψ 3/2 γν is suppressed both by the Planck mass and the small R-parity breaking couplings, so the lifetime is much longer than the age of the universe (Takayama, Yamaguchi 00), τ 3/2 26 s ( ) 2 λ ( m3/2 ) 3 ; 7 GeV (Note that this lifetime became very popular after PAMELA). What are the cosmic ray signatures? Gamma-ray flux of the order of EGRET excess!! Several other mechanisms to generate small R-parity breaking have been proposed (Mohapatra et al 08; Endo, Shindou 09,...) 7

LAUNCH07, March 2007, MPK Heidelberg: Extragalactic diffuse gamma-ray flux obtained from EGRET data (1998) MeV -1 s -1 sr -2. intensity, cm 2 E -3 V 2 3 4 energy (MeV) 5 analysis of Strong, Moskalenko and Reimer, astro-ph/0406254 (2004), astro-ph/0506359 (2005); subtraction of galactic component difficult astro-ph/0609768; extragalactic gravitino signal consistent with data for m 3/2 GeV; halo component may partly be hidden in anisotropic galactic gamma-ray flux wait for GLAST!! 8

Superparticle Mass Window (WB, Endo, Shindou 08) What are the constraints from leptogenesis and GDM on superparticle masses for unstable gravitinos, i.e. without BBN? GDM: upper bound on gluino mass for given reheating temperature; low energy observables: lower bound on NLSP. Connection is model dependent; assume gaugino mass unification (m gluino 6m bino ). Two typical examples (different ratios m NLSP /m gluino ), (A) χ NLSP : m 0 = m 1/2, a 0 = 0, tanβ ; (B) τ NLSP : m 0 = 0, m 1/2, a 0 = 0, tanβ. Low energy observables: m h > 114 GeV, BR(B d B s γ), m charged > 0 GeV. Possible hint for supersymmetry (Marciano, Sirlin 08), a µ (exp) a µ (SM) = 302(88) 11. 9

Stau and gravitino masses Left: (A) gravitino: m 3/2 < 490 GeV. Right: (B) stau: 0 GeV < m stau < 490 GeV. Red: mass range favoured by a µ.

Cosmic-Ray Signatures from Decaying Gravitinos (WB, Ibarra, Shindou, Takayama, Tran 09) Gravitino decays: ψ 3/2 γν;hν, Zν, W ± l, leads to continuous gammaray and antimatter spectrum: ψ 3/2 γx, px,e ± X; qualitative features from operator analysis (hierarchy: m SM m 3/2 m soft ): L eff = iκ { lγ λ γ ν D ν φψ λ + i } 2MP 2 lγ λ (ξ 1 g Y B µν + ξ 2 gw µν )σ µν φψ λ + h.c. R-parity breaking: κ; further suppression: ξ 1.2 = O(1/m 3/2 ) dim 5 : ψ 3/2 hν, Zν, W ± l ; continuous spectrum, i.e., single term correlates antiproton flux, PAMELA and Fermi! dim 6 : ψ 3/2 γν; gamma line 11

Minimal gravitino lifetime from antiproton flux Antiproton flux [GeV -1 m -2 s -1 sr -1 ] 0-1 -2-3 -4 Total flux MED Lifetime: 7.0E26 s BESS 95+97 BESS 95 IMAX 92 CAPRICE 94 CAPRICE 98 φ F = 500 MV -5 0.1 1 T [GeV] conservative propagation model (B/C ratio): MED model; require that total antiproton flux (including gravitino decays) lies below maximal flux from spallation (including astrophysical uncertainties) minimal lifetime; for m 3/2 = 200 GeV one finds τ min 3/2 (200) = 7 26 s. 12

PAMELA & Fermi vs electron dominance 1 PAMELA 08 HEAT 94/95/00 00 ATIC 08 Fermi LAT 09 HESS 08 Positron fraction e + /(e + + e ) 0.1 E 3 dn/de [GeV 2 m -2 s -1 ] 0 0.01 1 0 00 0 00 000 E [GeV] E [GeV] Input: m 3/2 = 200 GeV, τ 3/2 = 3.2 26 s, BR(ψ µ ± W,τ ± W ) BR(ψ e ± W ) (why?); background: Model 0 (Grasso et al, Fermi LAT 09) Conclusion: GALPROP & gravitino incompatible with PAMELA & Fermi!! [PAMELA & Fermi make CR signature for dark matter UNLIKELY!!] 13

PAMELA & Fermi vs flavour democracy 1 PAMELA 08 HEAT 94/95/00 00 ATIC 08 Fermi LAT 09 HESS 08 Positron fraction e + /(e + + e ) 0.1 E 3 dn/de [GeV 2 m -2 s -1 ] 0 0.01 1 0 00 0 00 000 E [GeV] E [GeV] Input: m 3/2 = 200 GeV, τ 3/2 = 7 26 s, BR(ψ l ± i W ) universal for i = e, µ, τ (theoretical model exists), background: Model 0. Conclusion: astrophysical sources needed to explain PAMELA & FERMI!! 14

Contribution from gravitino decays to positron fraction increases with increasing gravitino mass: 1 PAMELA 08 HEAT 94/95/00 00 ATIC 08 Fermi LAT 09 HESS 08 Positron fraction e + /(e + + e ) 0.1 E 3 dn/de [GeV 2 m -2 s -1 ] 0 0.01 1 0 00 E [GeV] 0 00 000 E [GeV] Input: m 3/2 = 400 GeV, τ 3/2 = 3 26 s, BR(ψ l ± i W ) universal for i = e, µ,τ, background: Model 0. Conclusion: gravitino contribution to electron/positron fluxes may be sizable, has to be complemented by astrophysical sources! 15

Contribution from gravitino decays to positron fraction decreases rapidly for gravitino masses below 200 GeV: 1 PAMELA 08 HEAT 94/95/00 00 ATIC 08 Fermi LAT 09 HESS 08 Positron fraction e + /(e + + e ) 0.1 E 3 dn/de [GeV 2 m -2 s -1 ] 0 0.01 1 0 00 E [GeV] 0 00 000 E [GeV] Input: m 3/2 = 0 GeV, τ 3/2 = 1 27 s, BR(ψ l ± i W ) universal for i = e, µ,τ, background: Model 0. Conclusion: gravitino contribution to electron/positron fluxes may be negligable, as for antiproton flux! 16

Predictions for the Gamma-Ray Spectrum Important contributions form extragalactic DM and DM in the Milky Way halo; typical branching ratio for gamma line (cf. operator analysis): ( ) 2 200 GeV BR(ψ 3/2 νγ) 0.02 ; m 3/2 Gamma-ray background presently uncertain, two analyses of EGRET data; Sreekumar et al: [ E 2dJ ] ( ) 0.1 E = 1.37 6 (cm 2 str s) 1 GeV, de GeV bg and Moskalenko et al: [ E 2dJ ] ( ) 0.32 E = 6.8 7 (cm 2 str s) 1 GeV. de GeV bg 17

Height of gamma line depends on energy resolution (assumed: σ(e)/e = 15%) and background; minimal lifetime from antiproton flux constraint give maximal gamma-ray flux: Sreekumar et al. Strong et al. Sreekumar et al. Strong et al. E 2 dj/de [(cm 2 str s) -1 GeV] -6-7 E 2 dj/de [(cm 2 str s) -1 GeV] -6-7 0.1 1 0 E [GeV] 0.1 1 0 E [GeV] left: m 3/2 = 200 GeV, τ 3/2 = 7 26 s; right: m 3/2 = 0 GeV, τ 3/2 = 1 27 s; improvement of energy resolution? 18

Hope for the LHC: τ -mass measurement (Ellis, Raklev, Oye 06) Events / 0.2 GeV / 30 fb-1 400 200 350 1 mτ [GeV] τ -mass can be measured from mτ = pmeas/βγmeas, slow τ s important! Background from muon tracks, accurate measurement of τ -mass possible 180 300 160 Cut on 0.3 < βγ < 0.6 54.1 / 41 χ2 / ndf m τ 152.485 ± 0.021 1 1.006 ± 0.019 σ τ 1 140 250 120 200 0 150 80 60 0 40 50 0 0 20 1 2 3 4 5 6 0 βγ 146 148 150 152 154 156 158 160 162 164 m τ [GeV] 1 analysis relevant for sufficiently long lifetimes, such that the τ -lepton leaves the detector; more work in progress... 19

SUMMARY Gravitino DM is viable possibility Gravitino DM is theoretically motivated: leptogenesis and/or gauge mediation... Decaying gravitino DM consistent with leptogenesis and BBN GALPROP & gravitino DM incompatible with PAMELA & Fermi, astrophysical sources needed!! Sizable excess in gamma-ray spectrum possible, in particular line at E γ m 3/2 /2. Gravitino DM can be discovered with Fermi LAT and/or falsified at the LHC!! 20